Unsteady thin film flow of a hybrid nanoliquid with magnetic effects

Kakanuti Malleswari, Sarojamma G.
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Abstract

Purpose This study aims to explore the thermal energy diffusion and flow features of a hybrid nanofluid in a thin film. In particular, the focus is to elicit the impact of shape factor in the backdrop of a magnetic field. The hybrid nanofluid is the amalgamation of various shaped nanoscale particles of copper and alumina in water. Design/methodology/approach The equations of motion and energy are modeled using the Tiwari–Das model. The differential equations governing the physics of the designed model have been obtained by the application of scaling analysis. To achieve quantitative outcomes, Runge–Kutta–Fehlberg numerical code along with shooting techniques is used. Validation of the derived outcomes with available data in literature reveals a greater accuracy of the numerical procedure used in this investigation. Findings The dynamics of the slender nano liquid film is explored eliciting the impact of various flow parameters. The rate of energy transport of the Cu-Al2O3/ water with blade-shaped nanoparticle, at a fixed Prandtl number (=2) is enhanced by 14.7% compared to that evaluated with spherical particles. The presence of hybrid nanoparticles has an affirmative impact in boosting the rate of heat transfer (RHT). The temperature and the rate of thermal diffusion of the hybrid nanofluid are more prominent than those of the Cu-H2O case. The numerical outcomes of this investigation are collated with the already published works as a limiting case and are found to be in good agreement. Originality/value The adopted methodology helped to obtain the results of the present problem. To the best of authors’ knowledge, it can be shown that the originality of the work with the table of comparison. There is a good agreement between present outcomes with the existed results.
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具有磁效应的混合纳米液体的非稳态薄膜流
目的 本研究旨在探索薄膜中混合纳米流体的热能扩散和流动特征。特别是,重点是探究形状因素在磁场背景下的影响。混合纳米流体是铜和氧化铝的各种形状纳米颗粒在水中的混合体。设计模型的物理微分方程是通过缩放分析获得的。为了获得定量结果,使用了 Runge-Kutta-Fehlberg 数值代码和射击技术。将得出的结果与文献中的现有数据进行验证,发现本研究中使用的数值程序具有更高的准确性。 研究结果探索了细长纳米液膜的动力学,并引出了各种流动参数的影响。在固定的普朗特数(=2)条件下,带有叶片形纳米粒子的 Cu-Al2O3/ 水的能量传输率与球形粒子相比提高了 14.7%。混合纳米粒子的存在对提高传热速率(RHT)有积极影响。与 Cu-H2O 情况相比,混合纳米流体的温度和热扩散率更为突出。本研究的数值结果与已发表的限制性案例进行了核对,发现两者非常吻合。据作者所知,对比表可以证明这项工作的原创性。目前的结果与已有的结果非常吻合。
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